Abstract

Recent advances in Passive Coherent Location (PCL) systems make combined active and passive radar sensor networks very attractive for both military and civilian air surveillance. PCL systems seem promising as cost-effective gap fillers of active radar coverage especially in alpine terrain and also as covert early warning sensors. However, PCL systems are sensitive to changes of Transmitters of Opportunity (ToO). Many approaches for energy-efficient target detection have been proposed for active radar sensor networks. However, energy-efficiency and topology optimization of combined active-passive radar sensor networks in realistic scenarios have been poorly studied until today. We here propose an unsupervised learning approach for topology optimization and energy-efficient detection in combined active-passive radar sensor networks. The interdependence of active and passive sensors in the network and the given target scenario is naturally accounted for by our approach. Optimal power budget and detection sectors of active radars and the most useful ToOs for each PCL sensor are simultaneously learned over time. This is a critical contribution for minimizing the need for active radar power budget and PCL computational resources. The power budget of active radars is minimized in a way that the added value of PCL sensors is fully exploited. We also demonstrate how our approach dynamically relearns to achieve robust performance when changes in the ToO of PCL sensors occur. We test our approach in a simulation suite for active-passive radar sensor networks using real-world air surveillance data and ToOs under real-world topographical conditions.

Highlights

  • IntroductionConventional Radar Sensor Networks (RSN) consist of multiple active radars (referred to as nodes) used to transmit waveforms in order to detect and track air targets

  • Conventional Radar Sensor Networks (RSN) consist of multiple active radars used to transmit waveforms in order to detect and track air targets

  • Given a set of active radars and Passive Coherent Location (PCL) sensors on certain locations, we addressed the problem of simultaneously determining the most useful ToOs for each PCL sensor and the most effective sectors and ranges for each active radar

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Summary

Introduction

Conventional Radar Sensor Networks (RSN) consist of multiple active radars (referred to as nodes) used to transmit waveforms in order to detect and track air targets. In our case we intend to minimize the usage of active radars by maximizing the usage of passive radar in the RSN, which is preferable for covert operation scenarios 1. Sensor Network Resource Allocation Learning game-theoretic approaches (Bacci et al, 2012) and network cost based strategies (Jiang et al, 2019). Such approaches are highly effective for RSNs consisting of solely active radar sensors, the widely awaited integration of Passive Coherent Location (PCL) systems pose challenges that still need to be addressed. Available PCL systems mainly use heuristics, on site signal measurements and human expertise to solve the above issues

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